DE102015207829A1 - Measuring phantom device for an imaging examination device - Google Patents

Abstract

The invention relates to a measuring phantom device (10) for an imaging examination device (22), characterized by a first support device (14) having a support portion, and at least two each configured as a bar or web, by means of one of the imaging examination device (22) physical unit to be imaged phantom elements (12), wherein the at least two phantom elements (12) respectively at the carrier portion of the first support means (14) are arranged and extending from a surface of the carrier portion projecting. The invention also relates to a method for setting a measurement parameter of an image analysis device (24) of an imaging examination device (22) using a measurement phantom device (10) according to the invention and a method for providing a measurement phantom device by means of a 3D printing device (36).

Description

The invention relates to a measuring phantom device for an imaging examination device, that is to say a device for evaluating, analyzing and setting a performance or property or a corresponding measuring parameter of an imaging examination device. An imaging device is understood to mean a medical device that is used for imaging methods in medical diagnostics, for example an X-ray device, a computed tomography device or a magnetic resonance tomograph.

While an x-ray machine captures a two-dimensional image by imaging a projection of a patient's volume onto a surface, a computed tomograph measures anisotropically, that is, the x-ray tube and detector rotate helically around the patient's longitudinal axis. In this case, a tilting of the ring tunnel (the so-called "gantry") is limited. Therefore, images in a sagittal plane and in a frontal plane (or coronal plane) require measurements of a volume from which they are then virtually cut out. In this case, axial layers or nearly axial layers can be measured with only half a revolution and opening angle of the tube. For each volume element, the absorption is then determined.

Even if today often seemingly isotropic data sets are generated, the physical conditions are very different in the different spatial directions. As a consequence, image artifacts are anisotropic; for example, if a human has two hip implants, X-ray radiation is completely absorbed. This attenuates the signal in other areas and lacks projections from the area between the hip implants, resulting in artifacts. Also, the image resolution is not really isotropic. For this problem, no solution is known from the prior art so far.

An object of the invention is the evaluation of image artifacts from anisotropies of the object and the measuring system.

The object is achieved by the objects according to the invention and the inventive method according to the independent patent claims. Advantageous developments of the invention are given by the dependent claims.

The invention is based on the idea to provide a Messphantomvorrichtung whose design is similar to an isotropic sea urchin. In this case, phantom elements radiate from a center and are distributed isotropically over all spatial directions. A phantom element is a component or a component of the measuring phantom device that is designed to have a physical property, for example an absorption behavior, a scattering property of a biological tissue, an imaging behavior (ie an imaging property) and / or a property for shielding, for example, X-radiation depict or simulate.

The devices according to the invention and the methods according to the invention make it possible in each case to recognize and evaluate image artifacts and thereby also make it possible to set and / or calibrate and / or standardize the imaging examination device.

The measuring phantom device according to the invention for the imaging examination device is characterized by a first carrier device, which has a carrier portion, and at least two phantom elements, each designed as a rod or web, to be imaged by means of a physical unit of measurement that can be provided by the imaging examination device, wherein the at least two phantom elements respectively at the carrier portion the first support means are arranged and extending from a surface of the carrier portion extending.

The physical unit of measurement may be, for example, a unit of measurement of X-radiation of a computer tomograph ("CT") or of a magnetic field of a magnetic resonance tomograph ("MRT"). In this case, a carrier device is understood to mean a component or a structure of the measuring phantom device on which or which the at least two phantom elements are arranged, for example a metal core or a connecting piece of the at least two phantom elements. The carrier portion is that portion at which the phantom elements are arranged directly. In other words, the phantom elements are connected to one another in a center of the measuring phantom device.

The measuring phantom device according to the invention can be used to simulate image artifacts. Furthermore, a standard for evaluating an image artifact due to scan anisotropy and / or due to metal foreign bodies or implants is provided.

In order to enable arranging a measuring substance or a measuring body in a cavity of at least one of the phantom elements, it can be provided according to a particularly preferred embodiment that at least one of the phantom elements is configured as a hollow cylinder or hollow cone, which preferably has an opening at an end opposite the carrier portion can be so can be open. In other words, the end can be designed as a passage opening or as a recess. In this case, a substance in any state of matter is understood as a measuring substance, for example a gas or a liquid such as, for example, oil or fat or salt-doped water, ie a salt solution. As a measuring body is an object or object understood from a solid, such as a metal body.

This embodiment has an effect, in particular, when used in magnetic resonance tomography, since the resonance and echo decay behavior of different measuring substances differs, and thus an image resolution can be determined and improved.

A further development provides that the measuring phantom device can have a closure device for covering or closing the opening, that is to say the open end, of the at least one of the phantom elements, for example a cover or a stopper. This effectively prevents leakage, slippage or leakage of the measuring substance or the measuring body.

According to a further embodiment, the at least two phantom elements can be arranged bilaterally symmetrically with respect to the carrier portion, or, with respect to a spherical shape of the carrier portion, radially symmetrically. The symmetry enables the most accurate possible result for the evaluation of an image artifact, since the phantom elements protrude equally in all spatial directions.

An advantageous distribution of the phantom elements in space can also be achieved if the carrier portion of the first carrier device is at least partially configured as a ball or spherical shell or hollow sphere, and that extend the at least two phantom radially projecting from the surface of the carrier portion.

A further carrier device, which has a carrier portion which extends parallel to the carrier portion of the first carrier device and which is arranged on at least one of the phantom elements, likewise leads to a higher stability of the measuring phantom device.

If according to a further embodiment of the measuring phantom device, the carrier portion of the further carrier device is connected to the opening or the open end of the at least one of the phantom elements, then the stability can be influenced particularly advantageously.

The measuring phantom device may have a holding device, on which the first carrier device and / or at least one of the phantom elements are arranged so as to be positioned between the source of the physical unit of measurement and a detector of the imaging examination device so that it can not slip during a measuring operation.

At least one of the phantom elements may consist entirely or partially of a different material than the first and / or the further carrier device, thereby advantageously allowing the phantom elements to have a different imaging, shielding or absorption behavior than the carrier device.

The above object is also achieved by a method for setting a measurement parameter of an image analysis device of an imaging examination device, for example an image resolution or a scattering amount of a noise. The inventive method is characterized by detecting a three- or multi-dimensional image of a Messphantomvorrichtung according to one of the described embodiments using the imaging examination device. This is followed by determining an image artifact of the image of the measurement phantom device, and adjusting the measurement parameter as a function of the determined image artifact. The inventive method enables the recognition of image artifacts and thereby also the setting and / or calibration and / or standardization of the imaging examination device or an image analysis device of the imaging examination device, for example a software. The method according to the invention described here can therefore also be referred to as a method for calibrating and / or standardizing the imaging examination device.

According to a particularly preferred embodiment of the method according to the invention, before the detection of a three- or more-dimensional image, provision of a measuring substance and / or a measuring body and / or a measuring body comprising the measuring substance can take place in a cavity of at least one of the phantom elements of the measuring phantom device. As a result, within the individual phantom elements, different media can be mimicked as a measurement substance or objects, such as, for example, a body fluid or an implant, and their absorption behavior can be simulated when the measurement phantom device is subjected to the physical quantity. This embodiment is particularly advantageous when used in a magnetic resonance tomography, since individual or all phantom elements with, for example, fat or oil or salt-doped water can be filled, so with a measuring substance whose resonance and Echoabklingverhalten is different than that of, for example, normal, approximately isotonic water. As a result, an imaging measurement can reveal whether a visual separation of, for example, fat and water within the measurement volume or a volume of a patient succeeds. Accordingly, the method can furthermore comprise that the measuring substance and / or the measuring body and / or the measuring body comprising the measuring substance at least partially consists of a material through which the measuring substance and / or the measuring body and / or the measuring body comprising the measuring substance has an imaging behavior which differs from an imaging behavior of isotonic water.

For example, for magnetic resonance imaging, it may be significant that the phantom elements are at least partially filled with an electrical conductor and / or a material having a short echo decay time similar to that of bone.

In order to simulate, for example, the absorption ratios of an implant implanted in a body device, it can be provided that prior to the detection of the three- or more-dimensional image, the measuring phantom device can be arranged in a measuring medium, for example in isotonic water.

The above object is also achieved by a method for providing a Messphantomvorrichtung, according to the first building land for controlling a 3D printing device, such as a 3D printer, are provided. The building land data describe an embodiment of a measuring phantom apparatus according to one of the embodiments of a measuring phantom apparatus described above. Based on the Bauplandaten the provision of the Messphantomvorrichtung done by the 3D printing device.

The method according to the invention allows an inexpensive production of a measuring phantom device, which makes it possible to quantify particularly difficult image acquisition problems.

A measuring phantom device produced in this way is likewise encompassed by the invention and likewise achieves the above-stated object. The measuring phantom device produced in this way has a particularly homogeneous and precise design. Since the measuring phantom device can be produced by the method according to the invention from very few individual parts or even in one piece, that is to say in one piece, the measuring phantom device produced in this way has particularly few or even no connection points of several components, for example welds or splices, which can influence the imaging. on. This measuring phantom device also allows the advantages already described above.

The invention will be explained in more detail by means of concrete embodiments with reference to the accompanying drawings. The exemplary embodiments explained below are preferred embodiments of the invention. In the embodiments, however, the described components of the embodiments each represent individual, independently of each other to be considered features of the invention, which each further independently form the invention and thus individually or in any other than the combination shown are to be regarded as part of the invention. Furthermore, the described embodiments can also be supplemented by further features of the invention already described. Functionally identical elements have the same reference numerals in the figures. It shows:

1 a schematic sketch of an embodiment of the measuring phantom device according to the invention,

2 a schematic sketch of a further embodiment of the measuring phantom device according to the invention,

3 2 shows a schematic sketch of a section of a further embodiment of the measuring phantom device according to the invention, wherein an embodiment of a phantom element is shown schematically by the section,

4 a schematic sketch of an embodiment of the method according to the invention for setting a measurement parameter of an image analysis device of an imaging examination device, and

5 a schematic diagram of an embodiment of the method according to the invention for providing a Messphantomvorrichtung.

The 1 schematically shows an embodiment of a Messphantomvorrichtung invention 10 for an imaging examination device (in the 1 not shown), for example for a computer tomograph or for a magnetic resonance tomograph. The measuring phantom device has a first carrier device 14 on, which may for example be designed as a central connector, on which all phantom elements 12 can be arranged. According to the invention, the measuring phantom device 10 at least two phantom elements 12 on, in the example of 1 for example 14 phantom elements 12 , The number of phantom elements 12 can thereby enable and improve a rating of an image artifact, with a high number of phantom elements 12 has beneficial effects on the accuracy of a measurement or calibration procedure. Advantageously, while the Messphantomvorrichtung 10 10 to 50 or 10 to 100 phantom elements 12 exhibit. Every phantom element 12 is at a carrier portion of the first carrier device 14 arranged, for example, at a designated portion of the support means 14 and / or a surface thereof.

Every phantom element 12 is configured in each case as a bar or web and extends from a surface of the carrier portion in the space, so that each phantom element 12 protrudes from the carrier portion. Indicates the measuring phantom device 10 as in the example of 1 , in a spherical shape, in other words, go from the first support means 14 or the carrier portion as the center radiating the phantom elements 12 from, which can be preferably distributed isotropically over all spatial directions.

The respective phantom element 12 may have a given imaging property, for example, to shield an X-ray. Corresponding materials are known to the person skilled in the art for this purpose, for example lead for shielding an X-radiation, or a plastic which can not be excited by a magnetic field when used in a magnetic resonance tomograph.

Preferably, the at least two phantom elements are 12 arranged bilaterally symmetrically with respect to the carrier portion, as exemplified in US Pat 1 shown.

The 2 shows a three-dimensional view of an exemplary Messphantomvorrichtung, in which a radially symmetrical arrangement of the phantom elements 12 in relation to the carrier portion or the carrier device 14 is shown.

The 1 further shows two optional further carrier devices 14 , which may be preferably configured in each case as a spherical shell. The further or the further carrier devices 14 can do so on the phantom elements 12 be arranged that their bilaterally symmetrical or radially symmetrical arrangement by the further or the other support means 14 can be stabilized. The first carrier device 14 and / or the further carrier device 14 may be made of any material based on the appropriate use of the measuring phantom device 10 can be adjusted. For example, the first carrier device 14 and / or the further carrier device 14 be made of a metal or plastic or a radiation-shielding material or a material that is not excited when subjected to a magnetic field.

A phantom element 12 can still have an open end 18 have, on which the further support means 14 at least partially arranged. The open end 18 can also be referred to as a passage opening or as a recess, and be configured for example as a blind hole or groove. Preferably, however, the phantom element 12 be designed as a hollow cylinder or hollow cone (see 3 ).

The 1 further shows a holding device 16 , For example, a holding plate made of a plastic, for example, on at least one phantom element 12 or on one of the carrier devices 14 can be arranged. This holding device 16 can take over the function of a stand or tripod and can preferably consist of a material by which the image acquisition by the imaging examination device can not be influenced.

The 3 shows by way of example a section of an embodiment of a Messphantomvorrichtung invention 10 , wherein in the cutout, the first, central support means 14 and by way of example two phantom elements 12 are shown. A first phantom element 12 , in the 3 shown on the left, shows an embodiment according to which the phantom element 12 a closure device, such as a lid may include. In this hollow cylinder, for example, a measuring substance 20 , For example, a fat suspension or a saline solution to be filled. Preferably, the measuring substance 20 For example, have an X-ray contrast agent. Through the closure device 13 can be designed as a hollow cylinder phantom element 12 then closed or covered.

The further in the 3 illustrated phantom element 12 can also be configured as a hollow cylinder and a measuring body 21 include, for example, a metal body or a fat body or a body made of a material familiar to those skilled, from which usually an implant can be made. By such a measuring body 21 For example, an implant can be readjusted into a patient's body and its imaging behavior can be simulated. In this way, image artifacts due to double oblique Foreign bodies or foreign bodies or implants oriented parallel to one another with, for example, high X-ray absorption are examined.

The 4 exemplifies an embodiment of a method according to the invention for setting a measurement parameter of an image analysis device 24 the imaging examination device 22 , The image analysis device 24 may include, for example, a microcontroller or a control device or an image analysis software, which may or may be adapted to an image analysis of an image of the imaging examination device 22 perform. In the example of 4 can the imaging examination device 22 include a computed tomography with a C-arm. Furthermore, in the 4 a target placement device 30 To see, for example, a patient bed, on the example of a container 26 with a measuring medium 28 , For example, isotonic water, may be arranged, in which the Messphantomvorrichtung 10 put in and from the holding device 16 can be positioned.

In this case, for example, a proportion of the phantom elements 12 with, for example, a fat suspension as the measuring substance 20 while, for example, another portion of the phantom elements 12 each with a metal body as a measuring body 21 can be filled. The measuring phantom device 10 can be used in this example as a dummy of a human tissue with multiple metal implants.

In a first method step S1, the detection of an example, three-dimensional image of the Messphantomvorrichtung takes place 10 by the exemplary computer tomograph. A detector of the imaging examination device 22 can receive the received signals, for example via a communication device 25 to an image analysis device 24 transmitted, for example, to a microprocessor with an image processing software, from the transmitted data an image of the Messphantomvorrichtung 10 can determine. On the basis of the image, an image artifact can then be determined by, for example, image processing software, for example by the image analysis device 24 generated image with a pre-programmed image of the measuring phantom device 10 can be compared, for example, the skilled person known algorithms for example, a pattern recognition or a segmentation can be used. Depending on the determined image artifact, for example, a corresponding measurement parameter can then be set (S2, S3). Based on a result of said comparison can then be calculated, for example, which of the measurement parameters of the image analysis device 24 can be scaled or changed.

An embodiment of a method according to the invention for providing the Messphantomvorrichtung invention 10 is exemplary in the 5 shown. Plan data 32 , which can be pre-programmed on a computer, for example, describe a spatial configuration of the Messphantomvorrichtung 10 and may, for example, take into account a specific use, for example, use in magnetic resonance imaging.

The construction land 32 can via a communication link to, for example, a control device 34 For example, a control unit or a microprocessor of the imaging examination device 22 , be transmitted. A control device 34 can then use a 3D printing device 36 control the 3D printing device 36 the measuring phantom device 10 provides.

In the 3D printing device 36 it may be, for example, a 3D printer, which, for example, a first tank 44 with a material 42 for a carrier device 14 can be filled. The 3D printing device 36 can still have another tank 44 comprising, for example, a material for the phantom elements 12 can be filled. Every tank 44 can do this at a respective nozzle 40 the 3D printing device 36 be arranged. Based on the construction land 32 becomes the measuring phantom device 10 then through the 3D printing device 36 manufactured, so for example printed, sprayed or by dripping or layers of the material 42 provided. The measuring phantom device 10 can, for example, on a carrier 46 be printed.

The embodiments described above illustrate the principle of the invention, a Messphantomvorrichtung 10 to provide or manufacture or use, which may preferably be configured similar to an isotropic sea urchin. In this case, preferably go from a first carrier device 14 at least two phantom elements are radiatively centered 12 from, which can be preferably distributed isotropically over all spatial directions.

• – die Messphantomvorrichtung 10 kann beispielsweise mit einem 3D-Druckverfahren in einem Stück hergestellt werden;
• – die vorzugsweise radial symmetrischen oder strahlenförmig abgehenden Phantomelemente 12 können vorzugsweise hohl ausgeführt sein und können beispielsweise an einem nach außen weisenden Ende eine Öffnung 18 aufweisen, über die beispielsweise eine Messsubstanz 20 und/oder ein Messkörper 21, beispielsweise ein Festkörper, in eines oder mehrere der Phantomelemente 12 eingeführt werden können. Diese können beispielsweise Röntgenkontrastmittel oder auch feste Materialien sein, aus denen üblicherweise Implantate hergestellt werden können. Auf diese Weise können Bildartefakte aufgrund doppelt schräger Fremdkörper mit hoher Röntgenabsorption untersucht werden;
• – die strahlenförmig abgehenden oder radial symmetrisch angeordneten Phantomelemente 12 können durch eine oder mehrere weitere Trägereinrichtungen 14, die jeweils vorzugsweise als Kugelschale ausgestaltet sein können, gehalten werden;
• – die weitere Trägereinrichtung 14 kann vorzugsweise auf den Enden der Phantomelemente 12 sitzen;
• – die erste Trägereinrichtung 14 oder die weitere Trägereinrichtung 14 oder ein oder mehrere Phantomelemente 12 können mit einer Halteeinrichtung 16, beispielsweise eine Halteplatte, ausgerüstet oder an einer solchen angeordnet sein;
• – die beispielsweise strahlenförmigen oder radial symmetrischen Phantomelemente 12 können beispielsweise in einer soliden Form aus einem zweiten Material integriert sein.

Optional advantageous features, which may also occur in any combination, may be:

• - the measuring phantom device 10 For example, it can be produced in one piece with a 3D printing process;
• - The preferably radially symmetric or radially outgoing phantom elements 12 may preferably be hollow and may, for example, at an outwardly facing end an opening 18 have, for example, a measuring substance 20 and / or a measuring body 21 For example, a solid, in one or more of the phantom elements 12 can be introduced. These can be, for example, X-ray contrast media or even solid materials from which implants can usually be produced. In this way image artifacts due to double oblique foreign objects with high X-ray absorption can be investigated;
• - The radially outgoing or radially symmetrically arranged phantom elements 12 can be through one or more other carrier devices 14 , which can each be preferably configured as a spherical shell, are held;
• - The further support device 14 may preferably be on the ends of the phantom elements 12 to sit;
• - The first carrier device 14 or the further carrier device 14 or one or more phantom elements 12 can with a holding device 16 , For example, a holding plate, equipped or arranged on such a;
• - The example, radial or radially symmetrical phantom elements 12 For example, they may be integrated in a solid form of a second material.

Among other things, the invention allows an inexpensive production of phantoms, which allows to quantify particularly difficult image acquisition problems.

Claims (14)

Measuring phantom device ( 10 ) for an imaging examination device ( 22 ), characterized by - a first carrier device ( 14 ), which has a carrier portion, and - at least two in each case designed as a bar or web, by means of one of the imaging examination device ( 22 ) phantom elements to be mapped to the physical unit of measure ( 12 ), wherein the at least two phantom elements ( 12 ) each at the carrier portion of the first carrier device ( 14 ) and extending from a surface of the carrier portion extending. Measuring phantom device ( 10 ) according to claim 1, characterized in that at least one of the phantom elements ( 12 ) is designed as a hollow cylinder or hollow cone, which preferably at an end opposite the carrier portion ( 18 ) is open. Measuring phantom device ( 10 ) according to claim 2, characterized by a closure device ( 13 ) for covering or closing the open end ( 18 ) of the at least one of the phantom elements ( 12 ). Measuring phantom device ( 10 ) according to one of the preceding claims, characterized in that the at least two phantom elements ( 12 ) are bilaterally symmetrical with respect to the carrier portion, or are radially symmetrical with respect to a spherical shape of the carrier portion. Measuring phantom device ( 10 ) according to one of the preceding claims, characterized in that the carrier portion of the first carrier device ( 14 ) is configured at least partially as a ball or spherical shell or hollow sphere, and that the at least two phantom elements ( 12 ) extend radially projecting from the surface of the carrier portion. Measuring phantom device ( 10 ) according to one of the preceding claims, characterized by a further carrier device ( 14 ), which has a carrier portion which is parallel to the carrier portion of the first carrier device ( 14 ) and at least one of the phantom elements ( 12 ) is arranged. Measuring phantom device ( 10 ) according to claim 6, characterized in that the carrier portion of the further carrier device ( 14 ) with the open end ( 18 ) of the at least one of the phantom elements ( 12 ) connected is. Measuring phantom device ( 10 ) according to one of the preceding claims, characterized by a holding device ( 16 ) at which the first carrier device ( 14 ) and / or at least one of the phantom elements ( 12 ) are arranged. Measuring phantom device ( 10 ) according to claim 4, characterized in that at least one of the phantom elements ( 12 ) consists entirely or partly of a different material than the first carrier device ( 14 ). Method for setting a measuring parameter of an image analysis device ( 24 ) of an imaging examination device ( 22 characterized by the steps of: - acquiring a three- or more-dimensional image of a measuring phantom device ( 10 ) according to one of claims 1 to 9 with the aid of the imaging examination device ( 22 , S1), - determining an image artifact of the image of the measuring phantom device ( 10 , S2), - in dependence of the determined image artifact setting of the measuring parameter (S3). A method according to claim 10, characterized by the step carried out prior to the detection of a three- or multi-dimensional image: - providing a measuring substance ( 20 ) and / or a measuring body ( 21 ) and / or a measuring substance ( 20 ) comprehensive measuring body ( 21 ) in a cavity of at least one of the phantom elements ( 12 ) of the measuring phantom device ( 10 ). Method according to claim 11, characterized in that the measuring substance ( 20 ) and / or the measuring body ( 21 ) and / or the measuring substance ( 20 ) comprehensive measuring bodies ( 21 ) consists at least partially of a material through which the measuring substance ( 20 ) and / or the measuring body ( 21 ) and / or the measuring substance ( 20 ) comprehensive measuring bodies ( 21 ) has an imaging behavior that differs from an imaging behavior of isotonic water. Method according to one of Claims 10 to 12, characterized by the step carried out before the detection of the three-dimensional or multidimensional image: - arranging the measuring phantom device ( 10 ) in a measuring medium ( 28 ). Method for providing a measuring phantom device ( 10 ), characterized by the steps of: - providing building land ( 32 ) for controlling a 3D printing device ( 36 ), whereby the construction land 32 ) an embodiment of a measuring phantom device ( 10 ) according to one of claims 1 to 9, and - based on the construction land-use data ( 32 ) Providing the Messphantomvorrichtung ( 10 ) by the 3D printing device ( 36 , S6, S7).

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